minutes. This should be enough time for the alcohol vapor to reach the

minutes. This should be enough time for the alcohol vapor to reach the

−

proper state. The high voltage clearing field should be off while

+

proper state.

−

the chamber cools.

==Look for Cosmic Ray Tracks==

==Look for Cosmic Ray Tracks==

Revision as of 14:18, 19 November 2013

A cloud chamber is a tool that reveals the path of cosmic
rays or other energetic charged particles. Because it permits us to measure
the track of these particles in three dimensions, even when they are
deflected by magnetic fields, the cloud chamber was important in
research during the 1930's that started our exploration of the nature of
cosmic rays and fundamental particles. For example, in 1932 Carl Anderson
discovered the positron in photographs of cosmic rays through cloud
chambers. The positron is the antiparticle for an electron, and it
is equally well described as an electron traveling backward in time!
Anderson won the Nobel Prize for this in 1936, and a year later he
discovered the muon, the electron's heavy cousin. Showers of cosmic
rays produced in the cascade from the primary's interaction with
the atmosphere contain electrons, positrons, and muons.

Contents

How They Work

The early cloud chambers were pulsed. Water or some other condensible
gas in a closed chamber was suddenly cooled by expanding it rapidly.
This produced a supersaturated vapor, but when charged particles passed
through it, a cloud would form along the particle track if the conditions
were just right. By 1950 a diffusion
cloud chamber was developed which operated continuously. It is simple
to make and operate, and for several years it was used to investigate
fundamental particles and cosmic rays.

Our diffusion cloud chamber is a replica of this design. It is a
an insulated metal box about 15 inches on a side. A large window on the
top allows you to look down on the black interior. Inside the box and
below the surface you see is space for a
dry ice -- frozen carbon dioxide (CO2). The dry ice cools the bottom pan
to about -78 C. The pan is covered with
methyl alcohol (wood alcohol).
The vapor of the methyl alcohol becomes supersaturated as warm
alcohol rises along the sides of the box and
diffuses toward
the cold pan at the bottom. The saturated vapor is illuminated through
windows in the side of the box.
The arrangement of a cloud chamber and an illuminating projector
is shown in the photo. We use an LED flashlight instead now.

Cloud chamber illuminated with a projector.

Dry ice cools
the interior of a cloud chamber where methyl alcohol
forms a supersaturated vapor. Cosmic rays passing through the vapor
cause it to condense and mark tracks of the particles.
A light source illuminates the tracks
from the side to make them
visible briefly.

Clean the Windows

Although the cloud chamber we will use for this experiment in the lab
has its own light sources, we will use an LED flashlight because it provides a brighter light through the chamber and less stray light that hides the tracks we seek. The lab cloud chamber also has power supply that is intended to help clear tracks, but we will not need it for this experiment.
Therefore, there is no need to have power supplied to the instrument, and for your safety make sure that
the power switch is ``off when
the chamber is open.

Check that the windows are clear. You may need to
clean them off with a little water on a paper towel. It helps if
you do this this just before you close the chamber. If you leave a thin
film of
water on the windows
they will be less likely to fog when the chamber is cooled.

Add Dry Ice

To see cosmic rays you will need to create supersaturated alcohol vapor
inside the chamber. The first step is to add the dry ice that will
cool the alcohol. The assistant will help crush solid CO2 (dry ice)
to a powder.
The dry ice should be enough to cover the Teflon plate that forms the
bottom of the
cloud chamber with a layer 1 to 2 cm deep.
If there is not enough, the temperature will not be uniform,
and convection currents
will interfere with track formation.
Place the dry ice on the Teflon inside the box; springs below the plate
will push it
into contact with the bottom of the chamber.
Because dry ice is so cold that it could
burn you, whoever handles it has to be very careful. Use a paper towel, a plastic bag, or gloves to protect your hands.
It is best to let the assistant do this for you, but you should observe
the process.
After the dry ice is in place, fasten the chamber back onto the
box. There are
hooks and clasps on the side that hold things in place.
Check to be sure that the chamber is level. There are three adjusting screws
on the bottom for this purpose.

Add the Alcohol

The bottom plate that goes inside the chamber has felt on one side. Pour a generous
amount of methyl alcohol into the bottom of the chamber and insert the
bottom plate felt side down.
Make sure that there is enough alcohol to
cover the bottom of the chamber and to saturate the felt completely. The
felt wrapped wires on the inside should also be saturated with alcohol.
The felt should be soaked until soggy, but there should not
be a puddle of
alcohol in the bottom. Too much alcohol makes an insulating layer, but
too little alcohol prevents vapor from forming.

Place the top on the chamber and make sure that it is securely shut. There
should be no gaps between the lid and the chamber. It
helps if there is a thin water film on the inside of the observation
window.
The assistant will help you to make certain that the amount of alcohol
is about right.

Adjust the Illumination

There are two tricky things about making the cloud chamber work well:
creating a supersaturated vapor and illuminating the chamber so that
you can see tracks. It works best if the light enters the chamber
without hitting the edge of the bottom pan. Once you think you have
the LED light adjusted right, turn it off and wait about 10
minutes. This should be enough time for the alcohol vapor to reach the
proper state.

Look for Cosmic Ray Tracks

Turn on the lamps. The room lights should be off.
Look down into the chamber. Near the bottom you should see a light fog
from large droplets. As you watch, suddenly a straight track will appear
when a charged particle zips through the chamber. Once you have
seen one track, it will be easier to recognize others. If you don't succeed
soon, ask for help. It is possible that things are working and you can't
find tracks because the lighting is wrong. Once tracks are visible,
experiment
with the high voltage clearing field. This may help to dissipate the
clouds that results from frequent track formation, but
usually we do not need to turn the high voltage
on at all.

Answer These Questions

With the help of your partner, count the tracks which form over a 1 minute period.

1.How many cosmic rays pass through this chamber each minute? (Each student who is doing this should make their own count.)

2. Were all the tracks similar, or were some distinctly different? Explain your answer and provide a sketch.

A radioactive beta particle source with the radiation counter.

Ask the assistant for help with the radioactive sources. We have alpha (He nuclei) and beta (electrons) sources on small needles that may be inserted into the side of the cloud chamber. The figure shows the beta source at the window of a particle counter. The counter measures the number of charged particle pairs created per second by the source in units of roentgens per second. A milli-roentgen is about 2 million charged particle pairs per second.

The sources may be inserted into the side of the cloud chamber.

First try the alpha source. Alpha particles are actually helium nuclei, but they are emitted in the decay of some heavy naturally radioactive elements. We have a very weak radioactive source on the tip end of a needle that can be inserted into the cloud chamber. The assistant will show you how to do this. You will notice immediately that there are very many alphas coming from the tip of the needle.

3. Describe the alpha particle tracks and how they differ from the cosmic ray tracks.

Now with the help of the assistant insert the beta particle source into the chamber.

4. Describe the beta particle tracks and how you distinguish them from the alphas.

If you were successful with the cloud chamber and you saw cosmic rays, and if you take our word for it that many of these were muons, then you have just seen special relativity at work. The muon lifetime was slower for you than it was for the muon, because the muon was moving past you. Suppose that the muons you saw were moving at 98\% of the speed of light, about 296,940 km/sec.

5. Use the time dilation formula with v/c=0.98 and figure out how long such a muon seems to us to live. Will these muons reach us from an altitude of 3000 meters, slightly less than 10,000 feet?

The volume of a box is

V = X x Y x Z

where X, Y, and Z are its dimensions.

6. Measure the chamber and calculate its volume. Your measurement should be made in centimeters, so that the volume you calculate will be in cubic centimeters.

7. In the same units, estimate your own volume. You may use any method you like, but explain what you did, and give your answer in cubic centimeters.

8. How much more volume do you have than the cloud chamber?

9. The probability that a cosmic ray will hit you is proportional to your volume. For example, if you are 100x larger than the cloud chamber, then 100x as many cosmic rays go through you as through the chamber each minute. How many cosmic rays go through you in one minute?

10. How many cosmic rays go through you in one day (24 x 60 minutes)?

Consequences

Cosmic rays may be responsible for the random changes in DNA that
create mutations and are part of the process of evolution for both
plants and animals. The Earth's magnetic field protects us from some
cosmic rays (clearly, not all), but the field is not constant. In
fact, the field reverses fairly often, every 100,000 to 1,000,000
years. Whenever the field does reverse, it goes through a period with no
field at all, and we are completely unprotected from low energy cosmic
rays. Add this one to the growing list of
likely astronomical catastrophes --

Overheating from the greenhouse effect when fossil fuels add too much CO2> to the atmosphere

Cancer from ultraviolet sunlight when the ozone hole caused by fluorocarbons spreads to low latitudes

Years of winter when sunlight is blocked by dust after an asteroid or comet hits the Earth

The loss of the biosphere after the evolution of the Sun ultimately destroys all water on the Earth